Automatic weighing apparatus



Oct. 31, 1939. D. w, RIPLEY 2.177.99

AUTOMATIC WEIGHING APPARATUS Filed Sept. 24, 1957 4 Sheets-Sheet 2 T F O O w 0 O I flaw/'0 2 52 #LJ BY Q MQ 9M ATTORNEY.

Oct. 31, 1939. D. w. RIPLEY 2,177,997

AUTOMATIC WEIGHING APPARATUS Filed Sept. 24, 1937 4 Sheets-Sheet 3 5/ FIE .EI

FII5 E INVENTOR.

Oct. 31, 1939. D. w. RIPLEY AUTOMATIC WEIGHING APPARATUS Filed Sept. 24, 1957 4 Sheets-Sheet 4 R m m v m ATTORNEY.

Patented Get. 31, 1939 ginger 7 2,177,997 AUTOMATIC WEIGHING APPARA'rcs David W. Ripley, Oakland, Caliifi, assignor of one-half to Alfred M. Blumer, Hillsborough, Calif.

Application September 24, 193%, Serial No. 165,518

4. Claims.

This invention relates generally to automatic equipment for weighing predetermined quantities of, a bulk material. The machine as disclosed herein has found successful application in the dried fruit industry, for weighing outmeasured quantities of dried fruit like prunes or raisins for packaging.

It is an object of the invention to provide a machine of the above character which will have a high degree of accuracy as compared to machines previously available. The accuracy of my machine is attributed to a number of different factors, including particularly however the manner in which electrical contact is established to effect final shut-off of material being supplied to the weighing hopper.

It is a further object of the invention to provide an improved automatic weighing machine having both a large main feed drum and a small dribble feed drum, together with a type of electrical control for the same which will insure a high degree of accuracy. The control mechanism is characterized by the use of two pairs of electrical contacts, associated with the weighing or balancing beam for the weighing hopper, together with damping means constructed in such a manner that one pair of contacts is retained positively closed, without chattering movement, until after the beam starts to swing in a direction to close the other pair of contacts. For intermediate positions of the weighing beam and positions immediately preceding closing of the second pair of contacts, the beam is substantially undamped.

Another object of the invention is to provide novel mechanism elements for carrying out cyclic operation of difierent parts of the automatic weighing machine, together with novel means forre-setting various mechanisms after they have been actuated.

Further objects of the invention will appear from the following description in which the preferred embodiment of the invention has been set forth in detail in conjunction with the accompanying drawings.

Referring to the drawings:

Fig. 1 is a side elevational view, illustrating a machine incorporating the present invention.

' Fig. 2 is a detail showing portions of the one revolution clutch for cycling the machine after a weighing operation, and which parts are hidden from View in Fig. 1.

Fig. 3 is a cross-sectional view taken along 55 the line 3-3 of Fig. 1

Fig. 4. is a cross-sectional detail, taken along the line. @---4 of Fig. 1.

Fig. 5 is a cross-sectional view taken along the line 5-5 of Fig. 3.

Fig. 6 is a circuit diagram showing the elec- 5 trical connections between the various tripping solenoids, the recycling switch, and the electrical contacts operated by. the balancing beam.

Fig. 7 is a side elevational view showing the main parts of the machine, and looking towards 10 the opposite side of the machine, from that illustrated in Fig. 1.

Fig. 8 is a detail illustrating the ratchet mechanism associated with the dribble feed drum,

and which is hidden from view in Fig. 7. 15

Fig. 9 is a cross-sectional detail illustrating the damping solenoid connected to the balancing beam.

Referring first to Fig. 1 of the drawings, the machine illustrated consists generally of an up- 20 per housing ill, with which certain working parts are associated, including particularly the large and small feed drums. Immediately below the housing ill there is a weighing hopper I and below the hopper H there is a receiving hopper 25 i2, for delivering the material being weighed to cartons or receptacles. The parts just mentioned together with the other working parts, are carried by a suitable support I3, which includes the uprights it, together with the crossmembers 0 l6, l1 and I8 (Fi 3).

I'he hopper it performs the main weighing operation, and it is mounted for limited vertical movement. Thus a balancing beam 2| is provided, which includes the spaced arms 22, ex- 35 tending forwardly upon opposite sides of the hopper H. The forward ends of these arms have fulcrum connections 23, with the side walls of the hopper ii, at points near the upper portion of this hopper. The lower portion of the 40 hopper is steadied against -swinging movement, by the spaced links 24, the forward ends of which have pivotal connections 26 with the lower portion of the hopper. The rear ends of the links have pivotal connections 21, with the depending stationary bracket 28. Balancing beam 2| has a fulcrum mounting 29 to brackets 3|, which are carried by the framing member Ill. The rearwardly extending arm 32 of the beam 2| carries a counter-weight 33, and adjustment of this counter-weight is possible by means of engagement of the attaching screws 34, through the slot 36. Arm 32 is also attached to a dash pct 31, and its free end extends into a housing 38, for associa- ,tion with the electrical control contacts. The

slot 39, in the housing 38, definitely limits swinging movement of the beam 2|, during operation of the machine.

Dash pot 31 can be best understood by reference to Fig. 9. It is constructed in such a manner as to aiford a considerable amount of damping when the arm 32 is near its lower limit, and to automatically remove substantially. all damping when the arm 32 is in intermediate positions or near its upper limit. The dash pot shown in Fig. 9, which makes possible this result, consists of a small cylinder 4|, adapted to contain a liquid like ordinary lubricating oil. Slidably extending into the upper end of this cylinder, there is a composite piston rod consisting of a sleeve or tube 42, and an inner rod 43. The upper end of sleeve 42 carries a nut 44, having threaded engagement with the upper portion of the rod 43. Above nut 44 there is a lock nut 46, and above this lock nut the rod 43 is connected to the lower end of a threaded rod 41 (Fig. 5). This rod extends through slot 36, and is adjust-ably attached to the arm 32, by means of the lock nuts 48.

The lower end of rod 43 (Fig. 9) slidably extends through a small guide 5|, which is disposed in the bottom of the cylinder 4 I. In the region of the guide 5| the cylinder is provided with a portion 4la which is machined to a substantially smaller diameter than the upper and remaining portion of the cylinder Mb. The lower end of sleeve 42 carries a disc 52, and immediately below this disc there is a second disc 53, carried by the rod 43. Disc 53 is provided with apertures 54. Assuming that discs 52 and 53 were in relatively tight contact, openings 54 would be closed. Under such conditions movement of disc 53 with in the region of the smaller diameter 4|a. would be damped a maximum extent, because all of the displaced liquid would necessarily pass through the clearance about the outer periphery of disc 53, and the adjacent walls of the cylinder. How ever, by adjusting the spacing between discs 52 and 53, the liquid can be vented an adjustable amount through openings 54, thus adjusting the amount of damping action. When the disc 53 is elevated into the enlarged portion 4lb of the cylinder, there is practically no damping action, because of the larger clearance which exists between the periphery of disc 53 and the adjacent walls of the cylinder. The connection of the dash pot to arm 32 is so adjusted, that when the arm 32 is in its lowermost position. disc 53 is within the smaller cylinder portion 4la, that is slightly below the position illustrated in Fig. 9. Therefore the dash pot exerts considerable damping to resist any fluttering of the beam in the proximity of this lower limit. As the beam is raised to intermediate or upper positions, there is substantially no damping, because for such positions the disc 53 is within the enlarged cylinder portion 4").

The end of the arm 32 which extends into housing 38, carries an electrical contact 56. This contact (which can be termed an upper contact) is adapted to engage and make electrical connection with contact 51, which has a suitable spring mounting to the housing 38. The lower side of the arm 32 also cooperates with a pair of contacts 58 and 59, which also are mounted in housing 38, and which are normally in open position. When arm 32 is swung to its lower limit it engages and presses the upper contact 58 down to close upon the contact 59. Although the circuit diagram of Fig, 6 will not be described at this point, it may be mentioned that 2 .1

ing 38 also carries an electromagnet 6|, in a position so that its magnetic pole is in close proximity with the upper face of magnetic arm 32, when this arm is in raised position. This electromagnet performs the holding or overloading operation and applies a holding or overloading force to the beam to retain contacts 56 and 5! closed, after these contacts have made initial engagement.

It may be explained at this point that opening of the contacts 58 and 59 in the cycle of operation of the machine, serves to disrupt operation of the larger feed drum, leaving however the so-called dribble feed drum in operation. When contacts 56 and 51 are closed the dribble feed drum is stopped, all further supply of 723.- terial to the weighing hopper is arrested, and material in this hopper is automatically discharged down into the receiver l2.

Referring now to Figs. 3 and 5, the automatic feed means employed includes the two drums 63 and 64, which can be termed respectively the main or large feed drum, and the dribble or small feed drum. Both of these drums are made of suitable metal, such as cast aluminum. Both 8 drums are loosely carried upon a horizontal shaft 66. The side walls 68 of the housing I 0 are shown provided with openings 69, through which the ends of the drums 63 and 64 extend. Spring pressed brake shoes ll can engage the end faces of the drums in order to afford sufiicient friction to avoid detrimental back-lash.

The periphery of each drum is provided with a plurality of longitudinally spaced annular ribs 12 (Figs. 3 and 5) and at circumierentially spaced points on these ribs, small extended lugs 13 are provided. All of the lugs 13 are aligned, in order to facilitate the conveyance of material. Extending across the forward side of both drums, there is a bar 14, provided with a plurality of stripping fingers 16. The upper ends of the stripping fingers 16 extend between the ribs 72.

Material being weighed is supplied to the upper sides of the drums 63 and 64, through the chute 11', which is formed in the upper part of the housing I 8. The back wall 18 of this chute has its lower end terminating in proximity with the periphery of the drum, while the front wall 19 is provided with a pair of adjustable gates BI and 82. Extending between the adjacent ends of the drums 83 and 64, there is a partition wall 83, whereby material dropping from the drums 63 and 64 is separately delivered from the housing Ill.

The power for operating the machine is supplied by a suitable source such as an electric motor 86 (Fig. 5), which can be provided with a conventional gear box 81, and is shown carried by the motor bracket 88. A chain 89 is shown connecting the drive sprocket 98 on the motor. with a sprocket 9| mounted upon the shaft 66. Incidentally it may be pointed out that this shaft has its end carried in suitable journals 92, supported by the frame of the machine.

The releasable drive connection between shaft 66, and the small drum 64, makes use of a pair of ratchet wheels 93 and 94, with wheel 93 fixed to shaft 66, and wheel 94 journalled upon the hub of wheel 93. A pawl 96 (Fig. 8) has a pivotal mounting with the side of the small drum, and is urged by spring 98, to engage the teeth of ratchet wheel 93. Fixed with respect to the pawl 96 there is an arm 99, the free end of which has a slot IOI. This slot engages within a pin I02, provided in the ratchet wheel 94. Normally pawl 96 engages the teeth of wheel 93, so that the drum 64 is driven in unison with shaft 66. However when pawl 96 is looked as bymeans to be presently described, the camming action or thrust exerted upon pin I02 is suificient to turn arm 99, and such turning movement is transmitted to pawl 86, in order to swing this pawl to disengaged position. A duplicate type of drive connection is employed for connecting shaft 66 with the large drum 63.

The means employed for locking the ratchet wheel 94, corresponding to the large drum 63, makes use of a trip finger I06 (Fig. 1) having a pivotal connection I01 with the side of the housing. This trip finger is provided with an arm I08, connected to one end of a biasing spring I09. It is also provided with a pin III, adapted to be engaged by a pivoted latch lever II2. Latch lever I I2 is in turn connected to a pull rod I I3, extending downwardly from the electric solenoid II4. Thus when the solenoid H4 is energized, latch I I2 is lifted, to permit the finger I06 to swing inwardly to engage the teeth of ratchet 94 for the large drum 63. The finger I06 is also provided with a depending arm II6, having a pin and slot connection III with a link H8. The other end of this link I I8 is connected to an arm or crank I I9, which in turn is mounted upon the shaft I2 I. As will be presently explained this shaft operates a gate for shutting off material from the large feed drum.

A finger I23 serves to engage the ratchet wheel 94 forthe small drum (see Fig. '7). This finger also has a pivotal mounting I24 to the side of the housing, and has a laterally extending arm I26, urged downwardly by the tension spring I21. This finger also has another depending arm I28, having a pin and slot connection I29 with the link I3I. The other end of this link has a pivotal connection with a crank I32, attached to shaft I33. A tension spring I34 is attached to link I3 I, and urges the shaft I33 in a clockwise direction, as viewed in Fig. 7. Finger I23 also carries a small mercury contactor I36, the purpose of which will be presently explained. A pin I31 is mounted upon the finger I23, and is engaged by a latch I38. This latch in turn is pivotally mounted upon the side of the housing, and is connected to the pull rod I39, of the electrical solenoid I4I. Therefore energizing of solenoid I4I trips the latch I38, thus permitting finger I23 to move forward towards engaged position, to immediately arrest rotation of the small drum 64. At the same time shaft I33 is permitted to rotate in a clockwise direction as viewed in Fig. 7, under the tension of spring I34.

Referring to Fig. 5, two gates I43 and I44 are disposed alongside the front of the large drum, but somewhat below this drum so that material dropping down from the large drum must pass between the gates, when the gates are open. The housing is open below these gates, so that material is free to fall down into the weighing hopper II. Gate I43 is mounted upon the shaft I2I, which as explained with reference to Fig. 1, carries the arm II9. Gate I44 is mounted upon the shaft I01, which is also the shaft to which finger I06 is secured. Thus simultaneously with releasing the finger I06 for the large drum, the

gates I43 and I44 are swung towards each other and upwardly, to closed position, to prevent further dropping of material from the large drum into the weighing hopper II. Similar shorter gates, not shown, are provided immediately in front of and somewhat below the small drum. In

this instance however one of these gates is attached to the shaft I33, and the other is attached to the shaft I24 which forms a pivotal mounting for the finger I23. 1

The weighing hopper I I is provided with a pair of lower dumping gates I5I, which are carried by the shafts I52. The outer end of one of these shafts is attached to an arm I53, while the other shaft is attached to a somewhat similar arm I54. These two arms are cross connected by the link I58. The free end of arm I54 also carries a pin I51, adapted to engage a latch I58. This latch is pivotally mounted upon the side of the hopper II, and when ngaged with the pin I51, serves to retain the gates in closed position, against the weight of material within the hopper. A tension spring IBI is also provided, which urges the gates towards closed position, but which will permit the gates to swing to open position under the weight of material within the hopper, after the latch I58 has been released.

Latch I58 is moved to released position by mechanism making use of a solenoid I62, which has a pull rod I63 connected to a lever I64. Lever I64 has a pivotal mounting I66 with the frame of the machine, and is provided with a small finger I61, carrying an adjustable set screw I68. When lever I64 is swung upwardly for actuation of solenoid I62, set screw I68 engages the free end of latch I58, thus moving this latch to disengaged position with respect to pin I51.

The free end of lever I64 is connected with the lower end of a rod IN, the upper end of which is connected to operate certain mechanism, including a one revolution clutch, for re-cycling the machine. Thus the upper end of this rod is shown engaging the lower side of a finger I12, which has a pivotal mounting I13 on a bracket plate I14. A spring pressed plunger I15 engages the upper side of finger I12, to urge the same in a counter-clockwise direction as viewed in Figs. 1 and 2. Referring particularly to Fig. 2, finger I12 is attached to a depending latch I16, the lower end of which releasably engages with a pin I11, on the arm I18. Arm I18 forms a part of the one revolution clutch, and is pivotally carried by an arm I19, the latter being loosely secured to the hub of a gear I8I (Fig. 3). The ratchet wheel I82 is fixed to the shaft-66, alongside the arm I19, and the teeth of this wheel are adapted to be engaged by a pawl I83. This pawl is spring pressed towards engaged position, and is mounted upon the same pivot pin, as the arm or finger I19. When pin I11 is engaged by the lower end of latch I16, then pawl I83 is retained out of engagement with the teeth of wheel I82. However, when latch I16 is moved to disengaged position, pawl I83 is immediately permitted to snap into engaged position with respect to the teeth on ratchet wheel I82, and thereupon the arm rotates with the ratchet wheel for one revolution, at the end of which pin I11 re-engages with latch I16, thus causing retraction of pawl I83.

Since arm I19 is caused to rotate one revolution after disengagement of latch I16, the same occurs with respect to the gear I8I. This gear or pinion engages another gear I86 (Fig. 3), the ratio of diameters being such that the drive ratio is two to one. Gear I86 carries two projecting cam members I81, which are adapted to successively engage a roller I88, carried by the pivotal lever I89. Lever I89 has a pivotal connection I9I to the frame of the machine, and its forward free end is connected to the upper end of a pull rod I92. The lower end of rod I92 has a slidable engagement with a frame part I93, whereby it is free to siide in a vertical direction. Rod I92 is provided with a lug I94, adapted to engage and elevate the finger I08, when the rod I92 is raised. Its lower portion also carries a block I96, which has an inclined cam surface I91. In case the discharge gates I5I of the weighing hopper do not automatically swing back to closed position after the material weighing hopper hasdischarged, upward movement of block I96 causes the inclined surface I91 to engage the pin I51, thus swinging this pin back into engagement with the latch I58.

The shaft I9I to whicharm I89 is attached, extends across the back of the machine, and on the other side of the machine it connects with a similar arm MI. The free end of this arm connects with the upper end of a rod 202, the lower end of which extends through finger I26, and carries a lug 203, whereby when the rod 202 is raised, finger I26 is swung upwardly to move finger I23 back into engagement with latch I38.

In the above description reference has been made to the large drum solenoid II4, the small drum solenoid Hi, the solenoid I62 which can be termed a trip solenoid, the holding or socalled overload electromagnet 6|, and the various electrical contacts and contactors. Suitable electrical connections for these parts is illustrated in Fig. 6. Lines LI and L2 connect to a suitable source of current supply, as for example the secondary of a step down transformer. The electromagnet 6| is shown connected in shunt with the terminals of the small drum solenoid I4I. Contacts 58 and 59, when closed, supply current from line LI, through solenoid II4, while the small drum solenoid I 4| and electromagnet H are deenergized. Solenoid H4 is so constructed that when energized it does not trip, but when de-energized it operates in the manner previously described, to disengage latch II2. When contacts 59 and 59 are permitted to open, the circuit through solenoid II 4 is interrupted, and therefore the solenoid II4 operates to perform the functions previously described. As contacts 56 ard 51 close, a circuit is completed from line Ll through contacts 56 and 51, and solenoid I, back to the line L2. Thus solenoid MI is energized, and at the same time the holding solenoid BI is energized. As previously pointed out energizing of solenoid I4I causes the latch I38 associated with the small drum, to be released. Contactor I36 is of the Mercoid type, operated by tilting movement. In normal position illustrated in Figs. 6 and '7, corresponding to engaged position of the latch I38, the contacts are opened. Therefore during such times the solenoid I62 is not energized. However when latch I38 is disengaged and finger I23 moves to engaged posi tion, the contacts are closed and the circuit completed through solenoid I62.

The lower receiving hopper is shown adjustably supported by rods 206 which depend from the frame of the machine. The lower end of this hopper is provided with gates 201, to facilitate guiding material into a carton.

Operation of the machine as a whole can be briefly reviewed as follows: Material such as raisins is supplied at a comparatively constant rate by a suitable conveying means, to the chute 11, in housing I (Fig. 5). As the material drops down into chute 11, it falls upon the upper sides of both the large and small drums. Since the drums at this time are in rotation the material is carried forwardly and then dropped downwardly through the two gates I43 and I44, into the weighing hopper II. Depending upon the speed at which the machine is set, the weighing hopper II fills up with material just short of the weight desired. At this time the hopper II moves downwardly a slight amount and arm 32 of the balancing beam 2|, moves upwardly a sufllcient amount to close the contacts 58 and 59. Closing of these contacts immediately results in arresting rotation of the large drum, and in closing the gates I43 and I44, in the manner previously described. It may be noted at this point that false operation of the large drum, is prevented by the damping action of dash pct 31, which causes positive opening of the contacts 58 and 59. As the small drum continues to operate, raisins continue to be discharged at a comparatively slow rate into the weighing hopper II, until the weight is up to the precise amount desired, at which time the arm 32 of the balancing beam reaches its upper limit to close the contacts 56 and 51. Closing of these contacts immediately disrupts the drive connection to the small drum, thus stopping the small drum, and at the same time the gates which cut off the discharge from the small drum close. Substantially simultaneously with these operations the latch I58 is tripped to permit the discharging gates I5I to swing downwardly and drop the contents into the receiving hopper. About this time the one way revolution clutch is set into operation, and in the course of rotation of gear I86 one-half revolution, one of the cam elements I81 swings lever I89 upwardly, which movement is accompanied by upward swinging movement of the lever 20I, on the other side of the machine. Upward swinging of these levers re-cycles the machine; that is, it re-sets the latches H2 and I38, and the latch I58 in connection with the discharge gate, and it also insures proper closing of the discharge gates for the weighing hopper. The large and small drums now commence a new cycle of operation, in which a new batch of material is delivered to the weighing hopper I I, in the manner previously described.

As has been previously pointed out, my machine has many desirable features, not found in machines of the prior art. One of its most valuable features is the accuracy with which it will Weigh various materials, such as raisins. Although several factors contribute to successful operation and accuracy, in particular the damping action of the ba ancing beam only for movements of the beam sufficient to open the contacts 58 and 59, assists in securing a delicate balance before closing of contacts 56 and 51. Also the action of the holding or over-load electromagnet 6|, precludes any false operation of the small drum with resulting inaccuracies, in that it retains contacts 56 and 51 closed, while the operations described are being completed.

I claim:

1. In an automatic weighing machine, a weighing hopper having limited movement in a vertical direction, means for applying balancing forces to said hopper, means for feeding material to be Weighed to said hopper, said last means including a main feed means and also a dribble feed means, means adapted to be tripped to interrupt supply of material from the main feed means to the hopper, means adapted to operate said lastnamed means responsive to initial downward movement of the hopper shortly before the same has received the total weight desired, means adapted to be tripped to interrupt supply of material from the dribble feed means to the hopper, an electrical circuit adapted to be closed to energize said last-named means, a pair of electrical contacts included in said electrical circuit and adapted to be closed to close said circuit, means to effect closing of said electrical contacts responsive to further downward movement of said hopper when the same has received the weight desired, and means for damping vertical movements of the hopper only for'movements near its uppermost limit, without appreciably damping movements of the hopper for intermediate and lower-most positions of the same. a

2. In an automatic weighing machine, a weighing hopper having limited movement in a vertical direction, means for applying balancing forces to said hopper, means for feeding material to be weighed tosaid hopper, said last means including a main feed means and also a dribble feed means, means adapted to be tripped to interrupt supply of material from the main feed means to the hopper, means adapted to operate said last-named means responsive to initial downward movement of the hopper shortly before the same has received thetotal weight desired, means adapted to be tripped to interrupt'sup ply of material from the dribble feed means to the hopper, an electrical circuit adapted to be closed to energize said last-named means, a pair of electrical contacts included in said electrical circuit and adapted to be closed to close said circuit, means to effect closing of said electrical contacts responsive to further downward movement of said hopper when the same has received the weight desired, and means for damping vertical movements of the hopper only for movements near its uppermost limit, without appreciably damping movements of the hopper for intermediate and lower-most positions of the same, said last means including a hydraulic dash pot attached to said balancing means.

3. In an automatic weighing machine, a weighing hopper, said hopper being movable in a vertical position between definite upper and lower limits, means for applying balancing forces to said hopper, means for feeding material to be weighed to said hopper, said last means including a main feed means and a dribble feed means, means adapted to be tripped to interrupt supply of material from the main feed means to the hopper, an electrical circuit for actuating said last-named means to trip the same, said circuit including a pair of controlling contacts adapted to make and break electrical connection responsive to movements of the hopper in the proximity of its upper limit, means adapted to be tripped to interrupt supply of material from the dribble feed means to the hopper, means for actuating said last-named means including a second electrical circuit, a pair of electrical contacts included in said second electrical circuit and adapted to be closed to close the electrical circuit, means responsive to downward movement of the hopper to a position adjacent its lower limit for closing said last-named electrical contacts, and electro-magnetic means for applying an over-load force to the balancing means immediately upon initial closing of said last-named contact.

4. In an automatic weighing machine, a weighing hopper, said hopper being movable in a vertical position between definite upper and lower limits, means for applying balancing forces to said hopper, means for feeding material to be weighed to said hopper, said last means including amain feed means and a dribble feed means, means adapted to be tripped to interrupt supply of material from the'main feed means to the hopper, an electrical circuit for actuating said last-named means to trip the same, said circuit including a pair of controlling contacts adapted to make and break electrical connection responsive to' movements of the hopper in the proximity of its upper limit, means adapted to be tripped to interrupt supply of material from the dribble feed means to the hopper, means for actuating said last-named means including a second electrical circuit, a pair of electrical contacts included in said second electrical circuit and adapted to be closed to close the electrical circuit, means responsive to downward movement of the hopper to a position adjacent its lower limit for closing said last-named electrical contacts, means for applying an overload to said balancing means immediately upon initial closing of said lastnamed contacts, and means for damping movements of said weighing hopper only for movements in the proximity of said upper limit.

DAVID W. RIPLEY. 

